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Auteurs principaux: Giddings, Steven B., Perkins, Julie
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.13351
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author Giddings, Steven B.
Perkins, Julie
author_facet Giddings, Steven B.
Perkins, Julie
contents Description of evolution between spatial slices in a general spacetime suffers from a significant difficulty: the states on the slices, in a given basis, are not related by a unitary transformation. This problem, which occurs in spacetime dimensions above two, is directly related to the infinite number of inequivalent representations of the canonical commutators, and in particular will arise for interacting theories in time-dependent spacetimes. We connect different facets of this issue, and discuss its possible resolution. It is directly related to discussions of failure of a standard Schrödinger picture of evolution, and of evolution via "many-fingered time." One requires a condition specifying a physical unitary equivalence class of states; in general this equivalence class evolves with time, and an important question is how it is determined. One approach to this in free theories is by imposing a Hadamard condition on the two point function. We explore a different approach, which also may be helpful for interacting theories, analyzing the structure of the state in a local limit, and relate these approaches. We also elucidate the non-Hadamard behavior of unphysical vacua, and discuss concrete examples of these approaches involving cosmological and black hole evolution. The issues are extended in the context of quantum dynamical geometry, and raise important questions for the proper description of the wavefunction of the universe and for the role of the Wheeler-DeWitt equation.
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publishDate 2025
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spellingShingle Challenges for describing unitary evolution in nontrivial geometries: pictures and representations
Giddings, Steven B.
Perkins, Julie
High Energy Physics - Theory
General Relativity and Quantum Cosmology
Description of evolution between spatial slices in a general spacetime suffers from a significant difficulty: the states on the slices, in a given basis, are not related by a unitary transformation. This problem, which occurs in spacetime dimensions above two, is directly related to the infinite number of inequivalent representations of the canonical commutators, and in particular will arise for interacting theories in time-dependent spacetimes. We connect different facets of this issue, and discuss its possible resolution. It is directly related to discussions of failure of a standard Schrödinger picture of evolution, and of evolution via "many-fingered time." One requires a condition specifying a physical unitary equivalence class of states; in general this equivalence class evolves with time, and an important question is how it is determined. One approach to this in free theories is by imposing a Hadamard condition on the two point function. We explore a different approach, which also may be helpful for interacting theories, analyzing the structure of the state in a local limit, and relate these approaches. We also elucidate the non-Hadamard behavior of unphysical vacua, and discuss concrete examples of these approaches involving cosmological and black hole evolution. The issues are extended in the context of quantum dynamical geometry, and raise important questions for the proper description of the wavefunction of the universe and for the role of the Wheeler-DeWitt equation.
title Challenges for describing unitary evolution in nontrivial geometries: pictures and representations
topic High Energy Physics - Theory
General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2507.13351